Investigation on the aerobic methanotrophic community and the dominant taxon Methylomarinum in seagrass ecosystem.

IF 6.2 2区环境科学与生态学 Q1 GENETICS & HEREDITY

Environmental Microbiome Pub Date : 2025-06-11 DOI:10.1186/s40793-025-00736-z

Tongyin Liang, Junde Dong, Weiguo Zhou, Xiaofang Huang, Hongbin Liu, Yuhang Zhang, Qingsong Yang, Manzoor Ahmad, Luxiang Chen, Juan Ling

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引用次数: 0

Abstract

Background: Methanotrophs are a key biological methane sink, and aerobic methanotrophs critically reduce wetland methane emissions under global climate change. However, despite their ecological significance, investigations on aerobic methanotrophs within seagrass ecosystems remain scant. In this study, microcosmic culture experiments were used to assess aerobic methane oxidation (AMO) potential and its drivers across a vertical gradient of seagrass sediments. Moreover, the methanotrophic community structure was characterized by amplicon sequencing, and the dominant methanotroph's metagenome-assembled genome (MAG) and metabolic pathway was investigated.

Results: Sediments of Halophila ovalis exhibited notable vertical differences in both physicochemical properties and methane oxidation rates. Furthermore, ammonium nitrogen (NH₄⁺-N) decreased with sediment depth, and was suggested by structural equation modeling (SEM) to significantly contribute to the vertical methane oxidation variability. Microbial community structure analysis revealed that type I methanotrophs were stimulated by methane addition and significantly impacted the oxidation of elevated methane, with Methylomarinum being the dominant taxon. Through metagenomic analysis, we assembled a phylogenetically novel methanotroph, Candidatus Methylomarinum sp. MAG81, which is distantly related to the extant Methylomarinum vadi IT-4. We conducted a comparative analysis of the two genomes and discovered that MAG81 not only possesses the capability for methane oxidation but also has the ability to participate in methanol oxidation via Xox-MDH. Furthermore, MAG81 also harbors nitrogen metabolism genes, particularly those involved in nitrogen fixation (nifHDK). This genetic characteristic suggests a potential role for MAG81 in facilitating the carbon and nitrogen cycles within seagrass ecosystems.

Conclusions: In summary, our study revealed that the vertical variation of NH₄⁺-N significantly affected methane oxidation and that type I methanotrophs, especially the genus Methylomarinum played an important role in oxidizing methane in seagrass sediments, shedding new insights into the methane abatement in the seagrass ecosystem, which is essential for climate change mitigation.

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海草生态系统中好氧甲烷营养群落及优势类群甲基藻的研究。

背景：甲烷氧化菌是重要的生物甲烷汇，在全球气候变化背景下，好氧甲烷氧化菌对减少湿地甲烷排放具有重要作用。然而，尽管它们具有重要的生态学意义，但对海草生态系统中好氧甲烷氧化菌的研究仍然很少。在本研究中，采用微观培养实验来评估海草沉积物垂直梯度上的好氧甲烷氧化（AMO）电位及其驱动因素。此外，通过扩增子测序对甲烷营养菌群落结构进行了表征，并对优势甲烷营养菌的宏基因组组装基因组（MAG）和代谢途径进行了研究。结果：卵状嗜盐菌沉积物在理化性质和甲烷氧化速率方面存在显著的垂直差异。此外，铵态氮（NH4+-N）随沉积物深度的增加而减少，结构方程模型（SEM）表明，铵态氮（NH4+-N）对甲烷氧化的垂直变异有重要影响。微生物群落结构分析表明，ⅰ型甲烷氧化菌受到甲烷添加的刺激，显著影响升高的甲烷氧化，其中甲基化菌为优势类群。通过元基因组分析，我们组装了一个系统发育上新的甲烷营养菌，Candidatus Methylomarinum sp. MAG81，它与现存的Methylomarinum vadi IT-4有远亲关系。我们对两个基因组进行了比较分析，发现MAG81不仅具有甲烷氧化能力，还具有通过Xox-MDH参与甲醇氧化的能力。此外，MAG81还含有氮代谢基因，特别是与固氮有关的基因（nifHDK）。这一遗传特征表明MAG81在促进海草生态系统中碳氮循环方面具有潜在的作用。综上所述，本研究揭示了NH4+-N垂直变化对海草沉积物甲烷氧化有显著影响，且I型甲烷氧化菌，尤其是甲基藻属在海草沉积物甲烷氧化中发挥了重要作用，为海草生态系统的甲烷减排提供了新的认识，这对减缓气候变化至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Environmental Microbiome Immunology and Microbiology-Microbiology

CiteScore

7.40

自引率

2.50%

发文量

审稿时长

13 weeks

期刊介绍： Microorganisms, omnipresent across Earth's diverse environments, play a crucial role in adapting to external changes, influencing Earth's systems and cycles, and contributing significantly to agricultural practices. Through applied microbiology, they offer solutions to various everyday needs. Environmental Microbiome recognizes the universal presence and significance of microorganisms, inviting submissions that explore the diverse facets of environmental and applied microbiological research.